Definitions & Customer Considerations

Stainless Steel Considerations

Stainless steel generally has good natural corrosion resistance in common uses but can still suffer degradation and discoloration if subject to certain environmental, physical conditions or lack of suitable maintenance schedule and servicing. In general, clean and smooth surfaces are preferred to rough finishes to encourage a protective oxide layer to be maintained and enable stainless steel to remain bright. Specifying the cleaning & maintenance of stainless steel surfaces by regular washing to avoid staining and dirt marks is highly recommended, especially when used in more severe environments. Natural rain can often be sufficient to remove basic contaminants but more frequent scheduled cleaning may be required when products are used in inner urban and more aggressive environments. Technical advice on appropriate cleaning techniques for specific situations is available from specialist cleaning firms. Stainless steel representative associations are another good contact to consult for the most up to date advice. Information on material grades, selection, specification, end usage and other topics is also available from these organizations.

Stainless Steel Specialist Websites of Interest

Care & Use of Threaded Products

Ronstan produces and supplies many threaded items. All are made to the relevant thread standard, gauging processes and supplied under ISO9001 quality assurance system.

Stainless steel is a material which when used in male / female threaded elements and loaded with an applied torque can “Gall” or “cold weld”. This occurs when the stainless steel oxide surface film breaks down as a result of direct metal to metal contact. Solid-phase welding takes place (whereby material is transferred from one surface to another via contact pick-up). The symptoms of galling include thread surface damage and permanent seizure of the thread. Galling can be minimized with the use of dissimilar metals. Other Ronstan products uses brass alloys on turnbuckle ranges and use of brass nuts for the load carrying nuts as used in cable systems.
If using stainless steel male / female threaded systems, use of high pressure lubrication compound is required to help reduce the possibility of thread seizure. Care using these lubricated products is required to ensure threads stay clean during installation / service. Suitable clean up of lubricants after installation is required to avoid staining and grime build up.

Protection of threads during transport & in preparation for installation must be done to avoid any thread damage. Keeping threads wrapped until final installation is recommended. Threads must be clean of burrs, dirt, coarse grime or sand to help reduce the possibility of thread seizure and ensure the correct functionality of the product. Use of a secondary tensioning system for pre-stressing tension members on-site may be required to achieve the desired tension forces and avoid thread or product damage.

Quality Assurance

Ronstan International Pty. Ltd. Operates in accordance with a Quality Management System accredited to AS/NZS ISO9001: 2015, covering the design, sale, manufacture and distribution of a range of architectural, marine and industrial products.

Environment and Sustainability

Ronstan is committed to reducing its impact on the environment through staff awareness and education, the use of responsible metal, paper, plastic and chemical recycling practices, water catchment-recycling for use within production processes, the use of energy efficient technologies which create advantages for the business and the environment. These initiatives are undertaken in conjunction with on-going government environmental programmes and other like-minded “Green” manufacturing and supply partners.

CUSTOMER CONSIDERATIONS

Factor of Safety
An appropriate factor of safety should be applied to Breaking Load figures to suit each application before choosing or specifying a particular product. For many industrial and safety related applications, and for some yachting applications, a factor of safety greater than two (2) should be used or may be required by law or other regulations. It is the customer’s responsibility to ensure that an appropriate factor of safety is used, and it should allow for factors including but not limited to safety implications, service life, fatigue (as may be caused by wave action, wind stresses or repetitive cyclical loading), type of load (e.g. cyclic, shock, rotational speed), orientation of load, environment (e.g. exposure to ultraviolet light, corrosion and stress corrosion). Note that a ‘safe working load’ is not specified as this is dependent on the factor of safety, which must be determined by the user relative to each application.

Useful Life
The useful life of any product is determined by the above factors and must be assessed in each application, and thus no guarantee can be provided for product life, load capacity or any other factor due to the variability in usage. In some jurisdictions government regulations require the replacement of rigging components within certain periods of time, usually every three to five years. You must ascertain whether any such regulations affect you. While every precaution is taken in the product design and manufacturing processes to minimise the effects of corrosion and stress corrosion, there are also preventative as well as corrective treatments that can be carried out after installation. Contact your local representative for further assistance and advice.

Cleaning and Maintenance of Stainless Steel

Ronstan recommends regular inspection of stainless steel products to ensure they remain free of contaminants that may cause discolouration or staining.
Depending on the type of finish on the material, site conditions, concentration of airborne contaminants and exposure to rain stainless steel may exhibit discolouration. Cleaning with a mild detergent, warm water and a soft cloth may assist with removal of discolouration.
In cases of severe build-up of grime, a domestic grade nylon or synthetic scouring pad can be used in conjunction with warm soapy water to clean stainless steel components, however abrasive pads should not be used on chrome or nickel plated components.
Under no circumstances should steel pads of any description be used in the cleaning process, Stainless steel can be contaminated by pick-up of carbon steel residue from these steel pads and this will cause corrosion.

Product Information Amendments
All catalogue information is subject to specification changes during a product’s life-cycle. Any alterations will be posted on the website – www.ronstan.com, which should be considered the most up to date source of product information.

DEFINITIONS

Yield LoadYield Load is the maximum static and/or dynamic load at which the product will still function without distortion, wear or permanent deformation of components. Above this load moving parts may seize and stainless steel components may begin to bend, stretch or otherwise deform. Yield loads should never be exceeded in use.

Yield StressYield Stress is a material property that describes the stress in the material above which permanent deformation is likely to occur. It is dependent on the load applied and the cross sectional area of the object.

Maximum Working Load (M.W.L.)
Maximum Working Load (M.W.L.) is the maximum static and/or dynamic load at which the product will still function without excessive friction, distortion, wear or permanent deformation of components. Above this load, bearing systems may fail, moving parts may seize and stainless steel or plastic components may begin to bend, stretch or otherwise deform. Maximum working loads should never exceed half of the breaking load and should never be exceeded in use.

Ultimate Load (ULT)Ultimate Load (ULT) is the load at, or around which, a major failure can be expected to occur to some part of the product’s structure when new.

The Yield and Ultimate loads detailed in the catalogue should only be considered in the context of the project application. Final product selection is the sole responsibility of the user and/or their consultants.

Maximum Working Load (M.W.L.)
Maximum Working Load (M.W.L.) is the maximum static and/or dynamic load at which the product will still function without excessive friction, distortion, wear or permanent deformation of components. Above this load, bearing systems may fail, moving parts may seize and stainless steel or plastic components may begin to bend, stretch or otherwise deform. Maximum working loads should never exceed half of the breaking load and should never be exceeded in use.

Breaking Load (B.L.)
Breaking Load (B.L.) is the load at, or around which, a major failure can be expected to occur to some part of the product’s structure when new. Plastic components may split, rivets may give way, shackles may break, and other metallic components may fracture. No product should be used at more than half of the breaking load, so as to provide a minimum safety factor of two (2).

Breaking StressBreaking Stress is a material property that describes the stress in the material above which catastrophic failure of the material is likely to occur. It is dependent on the load applied and the cross sectional area of the object.

Characteristic Breaking Load (C.B.L.)Characteristic Breaking Load (C.B.L) is the load at or around which a major failure can be expected to occur in a swaged cable system. The C.B.L is set at 10% below the B.L. of the wire cable, to allow for the typical reduction in strength of the cable after swaging.

Modulus of Elasticity (E)Modulus of Elasticity (E) is the measure of stiffness of a material; the ratio of tensile stress to tensile strain. It is the tendency of a material to elastically (not permanently) stretch under tensile load. E is a material property used in combination with the tensile load applied, the cross sectional area of the material, and the length of the object, to determine the amount of elastic stretch of the object under load.

Metallic Cross Sectional Area (C.S.A.)

The Metallic Cross Sectional Area is the sum of the cross sectional area of each of the individual strands of wire that make up a cable. It does not include the gaps between the individual strands and therefore is more accurate than just using the diameter of the overall cable to determine the cross sectional area.

We use cookies to enhance your experience whilst on our site, and improve our services by analysing our site traffic we also use them to enable social media features.
By closing this banner, scrolling or clicking a link or continuing to browse you agree to the use of cookies.AcceptRefuseCookie Policy